Probing mixed-genotype infections I: extraction and cloning of infections from hosts of the trypanosomatid Crithidia bombi.

We here present an efficient, precise and reliable method to isolate and cultivate healthy and viable single Crithidia bombi cells from bumblebee faeces using flow cytometry. We report a precision of >99% in obtaining single trypanosomatid cells for further culture and analysis ("cloning"). In the study, we have investigated the use of different liquid media to cultivate C. bombi and present an optimal medium for obtaining viable clones from all tested, infected host donors. We show that this method can be applied to genotype a collection of clones from natural infections. Furthermore, we show how to cryo-preserve C. bombi cells to be revived to become infective clones after at least 4 years of storage. Considering the high prevalence of infections in natural populations, our method provides a powerful tool in studying the level and diversity of these infections, and thus enriches the current methodology for the studies of complex host-parasite interactions.

Probing mixed-genotype infections II: high multiplicity in natural infections of the trypanosomatid, Crithidia bombi, in its host, Bombus spp.

Mixed-genotype infections have major consequences for many essential elements of host-parasite interactions. With genetic exchange between co-infecting parasite genotypes increased diversity among parasite offspring and the emergence of novel genotypes from infected hosts is possible. We here investigated mixed- genotype infections using the host, Bombus spp. and its trypanosome parasite Crithidia bombi as our study case. The natural infections of C. bombi were genotyped with a novel method for a representative sample of workers and spring queens in Switzerland. We found that around 60% of all infected hosts showed mixed-genotype infections with an average of 2.47±0.22 (S.E.) and 3.65±1.02 genotypes per worker or queen, respectively. Queens, however, harboured up to 29 different genotypes. Based on the genotypes of co-infecting strains, these could be putatively assigned to either 'primary' and 'derived' genotypes - the latter resulting from genetic exchange among the primary genotypes. High genetic relatedness among co-infecting derived but not primary genotypes supported this scenario. Co-infection in queens seems to be a major driver for the diversity of genotypes circulating in host populations.

Genetic exchange and emergence of novel strains in directly transmitted trypanosomatids.

The breeding structure of protozoan infections, i.e. whether and how frequently parasites exchange genes ("sexual reproduction"), is a crucially important parameter for many important questions; it also matters for how new virulent strains might emerge. Whether protozoan parasites are clonal or sexual is therefore a hotly debated issue. For trypanosomatids, few experimental tests of breeding structure exist to date and are limited to the vector-borne human diseases Trypanosoma brucei, Trypanosoma cruzi, and Leishmania major. We infected the natural host (Bombus terrestris) of the monoxenous parasite Crithidia bombi (Trypanosomatida) either with a single strain of the parasite or in mixed infections and tested for genetic exchange among co-infecting strains using microsatellite markers. We show that strains regularly exchange genetic material, with occasional self-crossing during mixed infections. Most offspring clones fit the expected allelic pattern from a standard Mendelian segregation. In some cases, alleles are lost or gained, leading to an entirely new genotype different from either parent. Genetic exchange in C. bombi therefore does occur and the process also leads to allelic loss or gain that could result from slippage during recombination. The majority of novel offspring types correspond to a recombination of parental alleles. The case of C. bombi demonstrates that directly transmitted, monoxenic trypanosomatids can also exchange genes. Sex therefore seems to be found in very different lineages of the trypanosomatids. Furthermore, the data allowed estimating a frequency at which C. bombi shows genetic exchange in populations.

Molecular divergence defines two distinct lineages of Crithidia bombi (Trypanosomatidae), parasites of bumblebees.

This study provides, for the first time, sequence data for the protozoan flagellates Crithidia bombi and Crithidia mellificae (Kinetoplastea: Trypanosomatidae). We amplified the partial sequences of the small subunit ribosomal RNA (SSU rRNA), glycosomal glyceraldehyde phosphate dehydrogenase (gGAPDH), cytochrome b (Cyt b), and the complete internal transcribed spacer region 1 (ITS1) of the ribosomal RNA gene region for 66 clones of C. bombi from Switzerland and Alaska. Furthermore, we sequenced the same stretch of SSU rRNA and gGAPDH for one isolate of C. mellificae from Switzerland. All four molecular markers classified the C. bombi samples into two distinct lineages A and B. Both lineages were found in the two sampling locations. Variation within lineages was small or non-existing. Sequence differences between lineages were 1.64% for SSU rRNA, 4.36% for gGAPDH, and 12.02% for Cyt b. The ITS1-sequences of lineages A and B have diverged so much that no alignment was possible. With regard to ITS1, we additionally found fragment length polymorphism (variation in microsatellite repeat numbers) as well as nucleotide diversity within each lineage. Furthermore, the sequences of SSU rRNA and gGAPDH of C. mellificae were different from both lineages of C. bombi. The separation of lineages A and B, based on sequence differences and phylogenetic reconstruction, is so pronounced as to characterize two species of "C. bombi." We propose to retain C. bombi for the more common lineage A and suggest the name Crithidia expoeki n. sp. for lineage B.